Finisar AN-2030 User manual

Brand: Finisar

Model: AN-2030

Category: Network transceiver modules

Type: User manual

AN-2030: Digital Diagnostic Monitoring Interface for Optical Transceivers F i n i s a r

9/26/02 Revision D Page 1

Application Note AN-2030 2

Digital Diagnostic Monitoring Interface 3

for SFP Optical Transceivers 4

1. Scope and Overview 6

This document defines an enhanced digital diagnostic monitoring interface available in 8

Finisar SFP and GBIC optical transceivers. The interface allows real time access to 9

device operating parameters, and it includes a sophisticated system of alarm and 10

warning flags which alerts end-users when particular operating parameters are outside 11

of a factory set normal range. The interface is fully compliant with SFF-8472, “Digital 12

Diagnostic Monitoring Interface for Optical Transceivers", revision 9.3. 13

These digital diagnostic features are implemented in all Finisar SFP transceivers that 15

contain a “D” in the part number suffix (for example, FTRJ-1319-7D-2.5), as well as 16

DWDM and CWDM GBICs. All next generation Finisar SFPs utilizing the new part 17

numbering scheme (e.g. FTRJ1621P1BCL) also have the same diagnostic capability. 18

The interface is an extension of the serial ID interface defined in the GBIC specification 20

as well as the SFP MSA. Both specifications define a 256-byte memory map in 21

EEPROM, which is accessible over a 2-wire serial interface at the 8 bit address 22

1010000X (A0h). The digital diagnostic monitoring interface makes use of the 8 bit 23

address 1010001X (A2h), so the originally defined serial ID memory map remains 24

unchanged. The interface is identical to, and is thus fully backward compatible with both 25

the GBIC Specification and the SFP Multi Source Agreement. The complete interface is 26

described in Section 3 below. 27

The operating and diagnostics information is monitored and reported by a Digital 29

Diagnostics Transceiver Controller (DDTC), which is accessed via a 2-wire serial bus. 30

Its physical characteristics are defined in Section 4. 31

2. Applicable Documents 35

Gigabit Interface Converter (GBIC). SFF document number: SFF-0053, rev. 5.5, 37

September 27, 2000. 38

Small Form Factor Pluggable (SFP) Transceiver MultiSource Agreement (MSA), 40

September 14, 2000. 41

Digital Diagnostic Monitoring Interface for Optical Transceivers: SFF-8472, Draft 43

Revision 9.3, August 1, 2002. 44

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3. Enhanced Digital Diagnostic Interface Definition 2

Overview 4

The enhanced digital diagnostic interface is a superset of the MOD-DEF interface 6

defined in the SFP MSA document dated September 14, 2000. The 2-wire interface pin 7

definitions, hardware, and timing are clearly defined there, as well as in Section 4 8

below. This section describes an extension to the memory map defined in the SFP 9

MSA. The enhanced interface uses the two wire serial bus address 1010001X (A2h) to 10

provide diagnostic information about the module’s present operating conditions. A 11

memory map is shown in Figure 3.1 below. 12

The transceiver generates this diagnostic data by digitization of internal analog signals. 14

Calibration and alarm threshold data is written during device manufacture. 15

In addition to generating digital readings of internal analog values, the device generates 17

various status bits based on comparison between current values and factory-preset 18

limits. 19

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Figure 3.1: Digital Diagnostic Memory Map 2

Specific Data Field Descriptions 38

The information in italics in Table 3.1 indicates fields that are specific to the digital 40

diagnostics functions. 41

2 wire address 1010000X (A0h)

2 wire address 1010001X (A2h)

127

255

Serial ID Defined by

SFP MSA (96 bytes)

Vendor Specific

(32 bytes)

Reserved in SFP

MSA (128 bytes)

Alarm and Warning

Thresholds (56 bytes)

Cal Constants

(40 bytes)

119

Real

Time Diagnostic

Interface (24 bytes)

247

User Writable

EEPROM (120 bytes)

Control Functions (8 bytes)

255

127

Password Entry (8 bytes)

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Table 3.1 Serial ID: Data Fields – Address A0 1

Data

Address

Size

(Bytes)

Name of

Field

Description of Field

BASE ID FIELDS

0 1 Identifier Type of serial transceiver (see table 3.2)

1 1 Ext. Identifier Extended identifier of type of serial transceiver

2 1 Connector Code for connector type (see table 3.3)

3-10 8 Transceiver Code for electronic compatibility or optical compatibility

(see table 3.4)

11 1 Encoding Code for serial encoding algorithm (see table 3.5)

12 1 BR, Nominal Nominal bit rate, units of 100 MBits/sec.

13 1 Reserved

14 1 Length(9µm) -

Link length supported for 9/125 µm fiber, units of km

15 1 Length (9µm) Link length supported for 9/125 µm fiber, units of 100 m

16 1 Length (50µm) Link length supported for 50/125 µm fiber, units of 10 m

17 1 Length (62.5µm)

Link length supported for 62.5/125 µm fiber, units of 10 m

18 1 Length (Copper)

Link length supported for copper, units of meters

19 1 Reserved

20-35 16 Vendor name SFP vendor name (ASCII)

36 1 Reserved DWDM channel spacing - DWDM modules only

37-39 3 Vendor OUI SFP vendor IEEE company ID

40-55 16 Vendor PN Part number provided by SFP vendor (ASCII)

56-59 4 Vendor rev Revision level for part number provided by vendor (ASCII)

60-61 2 Wavelength Laser wavelength

62 1 Reserved DWDM wavelength fraction - DWDM modules only

63 1 CC_BASE Check code for Base ID Fields (addresses 0 to 62)

EXTENDED ID FIELDS

64-65 2

Options Indicates which optional transceiver signals are implemented

(see table 3.6)

66 1

BR, max Upper bit rate margin, units of %

67 1

BR, min Lower bit rate margin, units of %

68-83 16

Vendor SN Serial number provided by vendor (ASCII)

84-91 8

Date code Vendor’s manufacturing date code (see table 3.7)

92 1

Diagnostic

Monitoring Type

Indicates which type of diagnostic monitoring is implemented (if

any) in the transceiver (see Table 3.8)

93 1

Enhanced

Options

Indicates which optional enhanced features are implemented (if any)

in the transceiver (see Table 3.9)

94 1

SFF-8472

Compliance

Indicates which revision of SFF-8472 the transceiver complies with.

(see table 3.11)

95 1

CC_EXT Check code for the Extended ID Fields (addresses 64 to 94)

VENDOR SPECIFIC ID FIELDS

96-127 32

Vendor Specific

Vendor Specific EEPROM

128-255 128

Reserved Reserved for future use.

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Identifier 1

The identifier value specifies the physical device described by the serial information. 2

This value shall be included in the serial data. The defined identifier values are shown in 3

table 3.2. Finisar SFP modules have this byte set to 03h. Finisar GBIC modules have 4

this byte set to 01h. 5

TABLE 3.2: Identifier values 6

Value Description of physical device

00h Unknown or unspecified

01h GBIC

02h Module/connector soldered to motherboard

03h SFP

04-7Fh

Reserved

80-FFh

Vendor specific

Extended Identifier 10

The extended identifier value provides additional information about the transceiver. 11

The field is set to 04h for all non-custom SFP and GBIC modules indicating serial ID 12

module definition. 13

Connector 15

The connector value indicates the external connector provided on the interface. This 16

value shall be included in the serial data. The defined connector values are shown in 17

table 3.3. Note that 01h – 05h are not SFP compatible, and are included for 18

compatibility with GBIC standards. Finisar optical SFP modules currently have this byte 19

set to 07h (optical LC connector). GBIC modules have the byte set to 01h (SC). 20

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TABLE 3.3: Connector values 2

Value Description of connector

00h Unknown or unspecified

01h

02h

Fibre Channel Style 1 copper connector

03h

Fibre Channel Style 2 copper connector

04h

BNC/TNC

05h

Fibre Channel coaxial headers

06h FiberJack

07h LC

08h MT-RJ

09h MU

0Ah SG

0Bh Optical pigtail

0C-1Fh

Reserved

20h HSSDC II

21h Copper Pigtail

22h-7Fh

Reserved

80-FFh

Vendor specific

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Transceiver 1

The following bit significant indicators define the electronic or optical interfaces that are 2

supported by the transceiver. At least one bit shall be set in this field. For Fibre Channel 3

transceivers, the Fibre Channel speed, transmission media, transmitter technology, and 4

distance capability shall all be indicated. The SONET Compliance Codes are described 5

in more detail in table 3.4a. 6

Table 3.4: Transceiver codes 7

Data

Addr

Bit

Description of transceiver Data

Addr

Bit

Description of transceiver

Reserved Standard Compliance Codes Fibre Channel link length

3 7-0 Reserved 7 7 very long distance (V)

4 7-5 Reserved 7 6 short distance (S)

SONET Compliance Codes 7 5 intermediate distance (I)

4 4 SONET reach specifier bit 1 7 4 long distance (L)

4 3 SONET reach specifier bit 2 Fibre Channel transmitter technology

4 2 OC 48, long reach 7 3-2 Reserved

4 1 OC 48, intermediate reach 7 1 Longwave laser (LC)

4 0 OC 48 short reach 7 0 Electrical inter-enclosure (EL)

5 7 Reserved 8 7 Electrical intra-enclosure (EL)

5 6 OC 12, single mode long reach 8 6 Shortwave laser w/o OFC (SN)

5 5 OC 12, single mode inter. reach 8 5 Shortwave laser w/ OFC (SL)

5 4 OC 12 multi-mode short reach 8 4 Longwave laser (LL)

5 3 Reserved 8 0-3 Reserved

5 2 OC 3, single mode long reach

5 1 OC 3, single mode inter. reach Fibre Channel transmission media

5 0 OC 3, multi-mode short reach 9 7 Twin Axial Pair (TW)

9 6 Shielded Twisted Pair (TP)

9 5 Miniature Coax (MI)

Gigabit Ethernet Compliance Codes 9 4 Video Coax (TV)

6 7-4 Reserved 9 3 Multi-mode, 62.5m (M6)

6 3 1000BASE-T 9 2 Multi-mode, 50 m (M5)

6 2 1000BASE-CX 9 1 Reserved

6 1 1000BASE-LX 9 0 Single Mode (SM)

6 0 1000BASE-SX

Fibre Channel speed

10 7-5 Reserved

10 4 400 MBytes/Sec

10 3 Reserved

10 2 200 MBytes./Sec

10 1 Reserved

10 0 100 MBytes/Sec

Bit 7 is the high order bit and is transmitted first in each byte.

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The SONET compliance code bits allow the host to determine with which specifications 1

a SONET transceiver complies. For each bit rate defined in Table 3.5 (OC-3, OC-12, 2

OC-48), SONET specifies short reach (SR), intermediate reach (IR), and long reach 3

(LR) requirements. For each of the three bit rates, a single short reach (SR) 4

specification is defined. Two variations of intermediate reach (IR-1, IR-2) and three 5

variations of long reach (LR-1, LR-2, and LR-3) are also defined for each bit rate. Byte 6

4, bits 0-2, and byte 5, bits 0-7 allow the user to determine which of the three reaches 7

has been implemented – short, intermediate, or long. Two additional bits (byte 4, bits 3-8

4) are necessary to discriminate between different intermediate or long reach variations. 9

These codes are defined in Table 3.4a. 10

Table 3.4a: SONET Reach Specifiers 11

Speed Reach Specifier bit 1 Specifier bit 2 Description

OC-3/OC-12/OC-48 Short 0 0 SONET SR compliant

OC-3/OC-12/OC-48 Intermediate 1 0 SONET IR-1 compliant

OC-3/OC-12/OC-48 Intermediate 0 1 SONET IR-2 compliant

OC-3/OC-12/OC-48 Long 1 0 SONET LR-1 compliant

OC-3/OC-12/OC-48 Long 0 1 SONET LR-2 compliant

OC-3/OC-12/OC-48 Long 1 1 SONET LR-3 compliant

Encoding 13

The encoding value indicates the serial encoding mechanism that is the nominal design 14

target of the particular SFP. The value shall be contained in the serial data. The defined 15

encoding values are shown in table 3.5. Finisar Gigabit Ethernet/Fibre Channel 16

transceivers have this byte set to 01h (8B/10B encoding), and SONET transceivers 17

(including all SONET multi-rate transceivers) are set to 05h (SONET Scrambled). 18

Table 3.5: Encoding codes 19

Code Description of encoding mechanism

00h Unspecified

01h 8B10B

02h 4B5B

03h NRZ

04h Manchester

05h SONET Scrambled

06h -FFh

Reserved

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BR, nominal 1

The nominal bit rate (BR, nominal) is specified in units of 100 Megabits per second, 2

rounded off to the nearest 100 Megabits per second. The bit rate includes those bits 3

necessary to encode and delimit the signal as well as those bits carrying data 4

information. A value of 0 indicates that the bit rate is not specified and must be 5

determined from the transceiver technology. The actual information transfer rate will 6

depend on the encoding of the data, as defined by the encoding value. 7

Length (9µ)-km 9

Note that this field is an addition to EEPROM data from the original GBIC definition. 10

This value specifies the link length that is supported by the transceiver while operating 11

in compliance with the applicable standards using single mode fiber. The value is in 12

units of kilometers. A value of 255 means that the transceiver supports a link length 13

greater than 254 km. A value of zero means that the transceiver does not support single 14

mode fiber or that the length information must be determined from the transceiver 15

technology. 16

Length (9µ) 18

This value specifies the link length that is supported by the transceiver while operating 19

in compliance with the applicable standards using single mode fiber. The value is in 20

units of 100 meters. A value of 255 means that the transceiver supports a link length 21

greater than 25.4 km. A value of zero means that the transceiver does not support 22

single mode fiber or that the length information must be determined from the transceiver 23

technology. 24

Length (50µ) 26

This value specifies the link length that is supported by the transceiver while operating 27

in compliance with the applicable standards using 50 micron multi-mode fiber. The 28

value is in units of 10 meters. A value of 255 means that the transceiver supports a link 29

length greater than 2.54 km. A value of zero means that the transceiver does not 30

support 50 micron multi-mode fiber or that the length information must be determined 31

from the transceiver technology. 32

Length (62.5µ) 34

This value specifies the link length that is supported by the transceiver while operating 35

in compliance with the applicable standards using 62.5 micron multi-mode fiber. The 36

value is in units of 10 meters. A value of 255 means that the transceiver supports a link 37

length greater than 2.54 km. A value of zero means that the transceiver does not 62.5 38

micron multi-mode fiber or that the length information must determined from the 39

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transceiver technology. It is common for the transceiver to support both 50 micron and 1

62.5 micron fiber. 2

Length (Copper) 4

This value specifies the minimum link length that is supported by the transceiver while 5

operating in compliance with the applicable standards using copper cable. The value is 6

in units of 1 meter. A value of 255 means that the transceiver supports a link length 7

greater than 254 meters. A value of zero means that the transceiver does not support 8

copper cables or that the length information must be determined from the transceiver 9

technology. Further information about the cable design, equalization, and connectors is 10

usually required to guarantee meeting a particular length requirement. 11

Vendor name 13

The vendor name is a 16 character field that contains ASCII characters, left-aligned and 14

padded on the right with ASCII spaces (20h). The vendor name shall be the full name of 15

the corporation, a commonly accepted abbreviation of the name of the corporation, the 16

SCSI company code for the corporation, or the stock exchange code for the corporation. 17

At least one of the vendor name or the vendor OUI fields shall contain valid serial data. 18

Finisar transceivers contain the text string “FINISAR CORP.” in this address. 19

DWDM Channel Spacing 21

Byte 36 is reserved (set to 00h) in the SFP MSA as well as in SFF-8472. Finisar 22

DWDM transceivers use this byte to indicate their channel spacing. DWDM channel 23

spacing is an 8 bit unsigned integer indicating the DWDM channel spacing in units of 24

gigahertz. This byte is set to 00h in all non-DWDM Finisar transceivers. 25

Vendor OUI 27

The vendor organizationally unique identifier field (vendor OUI) is a 3-byte field that 28

contains the IEEE Company Identifier for the vendor. A value of all zero in the 3-byte 29

field indicates that the Vendor OUI is unspecified. Finisar transceivers contain the 30

values 00h, 90h and 65h in these addresses. 31

Vendor PN 33

The vendor part number (vendor PN) is a 16-byte field that contains ASCII characters, 34

left-aligned and padded on the right with ASCII spaces (20h), defining the vendor part 35

number or product name. A value of all zero in the 16-byte field indicates that the 36

vendor PN is unspecified. 37

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Vendor Rev 1

The vendor revision number (vendor rev) is a 4-byte field that contains ASCII 2

characters, left-aligned and padded on the right with ASCII spaces (20h), defining the 3

vendor’s product revision number. A value of all zero in the 4-byte field indicates that 4

the vendor rev is unspecified. All legacy Finisar transceivers contain zero in all 4 bytes 5

or ASCII space (20h) in all four bytes or one of two place holders: “X1—“ or “1A—“. 6

Early versions of the digital diagnostic standard (SFF-8472), used a scale factor of 7

1µA/AD Count for interpreting laser bias current readings. SFF-8472 later changed the 8

scale factor to 2µA/AD Count. All Finisar modules using a scale factor of 2µA/AD Count 9

have an ASCII “A” written in byte 56 of this field. 10

Laser Wavelength 12

Nominal transmitter output wavelength at room temperature. This field is a 16 bit value 13

with byte 60 as high order byte and byte 61 as low order byte. The laser wavelength is 14

equal to the the 16 bit integer value in nm. This field allows the user to read the laser 15

wavelength directly, so it is not necessary to infer it from the transceiver “Code for 16

Electronic Compatibility” (bytes 3 – 10). This also allows specification of wavelengths 17

not covered in bytes 3 – 10, such as those used in coarse WDM systems. 18

DWDM Wavelength Fraction 20

Byte 62 is reserved (set to 00h) in the SFP MSA as well as SFF-8472. Finisar DWDM 21

transceivers use this byte in conjunction with bytes 60-61 to indicate the DWDM 22

transceiver laser wavelength. Bytes 60-61 provide the integer wavelength in units of 23

nm. In DWDM transceivers, by 62 provides the fractional wavelength in units of 24

0.01nm. Thus the wavelength for a particular DWDM transceiver is given by: 25

(byte 60,61) + (byte 62 * 0.01nm). In all non-DWDM Finisar transceivers, this byte is set 26

to 00h. 27

CC_BASE 29

The check code is a one byte code that can be used to verify that the first 64 bytes of 30

serial information in the SFP is valid. The check code shall be the low order 8 bits of the 31

sum of the contents of all the bytes from byte 0 to byte 62, inclusive. 32

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Options 1

The bits in the option field shall specify the options implemented in the transceiver as 2

described in table 3.6. StandardFinisar SFP transceivers do not implement TX_FAULT 3

or RATE_SELECT, so byte 65 set to 00010010b. 4

Table 3.6: Option values 6

Data

Address

Bit Description of option

64 7-0 Reserved

65 7-6 Reserved

65 5 Indicates if RATE_SELECT is implemented. Finisar does not

implement this feature.

NOTE: Lack of implemention does not indicate lack of

simultaneous compliance with multiple standard rates.

Compliance with particular standards should be determined

from Transceiver Code Section (Table 3.4)

65 4 TX_DISABLE is implemented and disables the serial output.

65 3 TX_FAULT signal implemented.

65 2 Loss of Signal implemented, signal inverted from definition in

Table 1 of the SFP MSA.

NOTE: This is not standard SFP/GBIC behavior and should

be avoided, since non-interoperable behavior results.

65 1 Loss of Signal implemented, signal as defined in Table 1 of

the SFP MSA.

65 0 Reserved

BR, max 8

The upper bit rate limit at which the transceiver will still meet its specifications (BR, max) 9

is specified in units of 1% above the nominal bit rate. A value of zero indicates that this 10

field is not specified. 11

BR, min 13

The lower bit rate limit at which the transceiver will still meet its specifications (BR, min) 14

is specified in units of 1% below the nominal bit rate. A value of zero indicates that this 15

field is not specified. 16

Vendor SN 18

The vendor serial number (vendor SN) is a 16 character field that contains ASCII 19

characters, left-aligned and padded on the right with ASCII spaces (20h), defining the 20

vendor’s serial number for the transceiver. A value of all zero in the 16-byte field 21

indicates that the vendor PN is unspecified. 22

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Date Code 2

The date code is an 8-byte field that contains the vendor’s date code in ASCII 3

characters. The date code is mandatory. The date code shall be in the format specified 4

by table 3.7. 5

Table 3.7: Date Code 6

Data

Address

Description of field

84-85

ASCII code, two low order digits of year. (00 = 2000).

86-87

ASCII code, digits of month (01 = Jan through 12 =

Dec)

88-89

ASCII code, day of month (01 - 31)

90-91

ASCII code, vendor specific lot code, may be blank

Diagnostic Monitoring Type 9

“Diagnostic Monitoring Type” is a 1 byte field with 8 single bit indicators describing how 10

diagnostic monitoring is implemented in the particular transceiver (see Table 3.8). 11

Bit 6, address 92, is set in Finisar ‘7D’ SFPs, 'P' SFPs under the new part numbering 12

scheme, and WDM GBICs, indicating that digital diagnostic monitoring has been 13

implemented. Received power monitoring, transmitted power monitoring, bias current 14

monitoring, supply voltage monitoring and temperature monitoring are all implemented. 15

Additionally, alarm and warning thresholds are written as specified in this document at 16

locations 00 – 55 on 2 wire serial address 1010001X (A2h) (see Table 3.14). 17

If bit 5, “internally calibrated”, is set, the transceiver reports calibrated values directly 18

in units of current, power etc. If bit 4, “externally calibrated”, is set, the reported 19

values are A/D counts which must be converted to real world units using calibration 20

values read using 2 wire serial address 1010001X (A2h) from bytes 55 - 95. Finisar 21

transceivers use both calibration types so it is necessary to read bit 5 in order to 22

properly interpret transceiver data. 23

Bit 3 indicates whether the received power measurement represents average input 24

optical power or OMA. If the bit is set, average power is monitored. If it is not, OMA is 25

monitored. Finisar transceivers report “average power” and thus bit 3 is set. 26

Bit 2 indicates whether or not a special “address change” sequence (described in SFF-27

8472) is required. This sequence is NOT required in Finisar modules. Information at 28

both 2-wire addresses (A0h and A2h) may be accessed simply by using the appropriate 29

address during the 2-wire communication sequence. 30

Finisar SFP/GBIC transceivers thus have 0b01111000 written at address 92 if they are 31

internally calibrated, and 0b01011000 written at address 92 if they are externally 32

calibrated. Note that internally calibrated devices can be treated as externally calibrated 33

devices because the external calibration constants are set to 1 or 0 as appropriate. 34

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Table 3.8: Diagnostic Monitoring Type 1

Data Address Bits Description

92 7

Reserved for legacy diagnostic

implementations. Must be ‘0’ for compilance

with this document.

92 6

Digital diagnostic monitoring implemented

(described in this document). Must be ‘1’ for

compliance with this document.

92 5 Internally Calibrated

92 4 Externally Calibrated

92 3

Received power measurement type

0 = OMA, 1 = Average Power

92 2

Address change required see section above,

“addressing modes”

92 1-0 Reserved

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Enhanced Options 1

“Enhanced Options” is a 1 byte field with 8 single bit indicators which describe the 2

optional digital diagnostic features implemented in the transceiver. Since transceivers 3

will not necessarily implement all optional features described in this document, the 4

“Enhanced Options” bit field allows the host system to determine which functions are 5

available over the 2 wire serial bus. A ‘1’ indicates that the particular function is 6

implemented in the transceiver. Bits 3 and 6 of byte 110 (see Table 3.17) allow the 7

user to control the Rate_Select and TX_Disable functions. If these functions are not 8

implemented, the bits remain readable and writable, but the transceiver ignores them. 9

Finisar transceivers with alarm and warning flags enabled contain the value 10

0b10010000 at location 93. 11

Table 3.9: Enhanced Options 12

Data Address Bits Description

93 7

Optional Alarm/warning flags implemented for

all monitored quantities (see Table 3.18)

93 6

Optional Soft TX_DISABLE control and

monitoring implemented

93 5

Optional Soft TX_FAULT monitoring

implemented

93 4

Optional Soft RX_LOS monitoring

implemented

93 3

Optional Soft RATE_SELECT control and

monitoring implemented

93 2-0 Reserved

Note that the “soft” control functions - TX_DISABLE, TX_FAULT, RX_LOS, and 16

RATE_SELECT do not meet the timing requirements specified in the SFP MSA section 17

B3 “Timing Requirements of Control and Status I/O” and the GBIC Specification, 18

revision 5.5, (SFF-8053), section 5.3.1, for their corresponding pins. The soft functions 19

allow a host to poll or set these values over the serial bus as an alternative to 20

monitoring/setting pin values. Timing is vendor specific, but must meet the 21

requirements specified in Table 3.10 below. 22

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Table 3.10: I/O Timing for Soft Control & Status Functions 2

Parameter Symbol Min Max Units Conditions

TX_DISABLE assert time t_off 100 ms Time from TX_DISABLE bit set

until optical output falls below

10% of nominal

TX_DISABLE deassert time t_on 100 ms Time from TX_DISABLE bit

cleared

until optical output rises

above 90% of nominal

Time to initialize, including

reset of TX_FAULT

t_init 300 ms From power on or negation of

TX_FAULT using TX_DISABLE;

serial communication possible

TX_FAULT assert time t_fault 100 ms Time from fault to TX_FAULT bit

set.

LOS assert time t_loss_on 100 ms Time from LOS state to RX_LOS

bit set

LOS deassert time t_loss_off 100 ms Time from non-LOS state to

RX_LOS bit cleared

Rate select change time T_rate_sel

100 ms Time from change of state of Rate

Select bit

until receiver

bandwidth is in conformance with

appropriate specification

Serial ID clock rate f_serial_cl

ock

100 kHz n/a

Analog parameter data ready t_data 1000 ms From power on to data ready, bit

0 of byte 110 set

measured from falling clock edge after stop bit of write transaction.

SFF-8472 Compliance 4

Byte 94 contains an unsigned integer that indicates which feature set(s) are 5

implemented in the transceiver. 6

Table 3.11: SFF-8472 Compliance 8

Data Address Value Interpretation

94 0

Digital diagnostic functionality not included or

undefined.

94 1

Includes functionality described in Rev 9.3

SFF-8472.

94 2 TBD

94 3 TBD

CC_EXT 10

The check code is a one byte code that can be used to verify that the first 32 bytes of 11

extended serial information in the SFP is valid. The check code shall be the low order 8 12

bits of the sum of the contents of all the bytes from byte 64 to byte 94, inclusive. 13

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Diagnostics 2

2 wire serial bus address 1010001X (A2h) is used to access measurements of 3

transceiver temperature, internally measured supply voltage, TX bias current, TX output 4

power, received optical power, and two additional quantities to be defined in the future. 5

The values are interpreted differently depending upon the option bits set at address 92. 6

If bit 5 “internally calibrated” is set, the values are calibrated absolute measurements, 7

which should be interpreted according to the section “Internal Calibration” below. If bit 4 8

“externally calibrated” is set, the values are A/D counts, which are converted into real 9

units per the subsequent section titled “External Calibration”. 10

Measured parameters are reported in 16 bit data fields, i.e., two concatenated bytes. 11

To guarantee coherency of the diagnostic monitoring data, the host is required to 12

retrieve any multi-byte fields from the diagnostic monitoring data structure (IE: Rx Power 13

MSB - byte 104 in A2h, Rx Power LSB - byte 105 in A2h) by the use of a single two-14

byte read sequence across the serial interface. 15

Measurements are calibrated over specified device operating temperature and voltage 16

and should be interpreted as defined below. Alarm and warning threshold values 17

should be interpreted in the same manner as real time 16 bit data. 18

Internal Calibration 19

1) Internally measured transceiver temperature. Represented as a 16 bit signed twos 20

complement value in increments of 1/256 degrees Celsius, yielding a total range of –21

128°C to +128°C. Temperature measurement is valid from –40°C to +125°C with an 22

accuracy of ± 3°C. The temperature sensor is located in the center of the module 23

and is typically 5 to 10 degrees hotter than the module case. See Tables 3.12 and 24

3.13 below for examples of temperature format. 25

2) Internally measured transceiver supply voltage. Represented as a 16 bit unsigned 26

integer with the voltage defined as the full 16 bit value (0 – 65535) with LSB equal to 27

100 µVolt, yielding a total range of 0 to +6.55 Volts. Accuracy is ±100mV. 28

3) Measured TX bias current in µA. Represented as a 16 bit unsigned integer with the 29

current defined as the full 16 bit value (0 – 65535) with LSB equal to 2 µA, yielding a 30

total range of 0 to 131 mA. Accuracy is ± 10%. Early versions of the digital 31

diagnostic standard (SFF-8472) used a scale factor of 1µA/AD Count for interpreting 32

laser bias current readings. SFF-8472 later changed the scale factor to the current 33

value of 2µA/AD Count. All Finisar modules using a scale factor of 2µA/AD Count 34

have an ASCII “A” written in byte 56 of the ‘vendor rev’ field (see table 3.1). Legacy 35

Finisar modules using a scale factor of 1µA/AD Count contain either zero or ASCII 36

space (20h) or one of two place holders: “X1—“, “1A—“, in location 56. 37

4) Measured TX output power in mW. Represented as a 16 bit unsigned integer with 38

the power defined as the full 16 bit value (0 – 65535) with LSB equal to 0.1 µW, 39

yielding a total range of 0 to 6.5535 mW (~ -40 to +8.2 dBm). Data is factory 40

AN-2030: Digital Diagnostic Monitoring Interface for Optical Transceivers F i n i s a r

9/26/02 Revision D Page 18

calibrated to absolute units using the most representative fiber output type. 1

Accuracy is ±3dB. Data is not valid when the transmitter is disabled. 2

5) Measured RX received average optical power in mW. Represented as a 16 bit 3

unsigned integer with the power defined as the full 16 bit value (0 – 65535) with LSB 4

equal to 0.1 µW, yielding a total range of 0 to 6.5535 mW (~ -40 to +8.2 dBm). 5

Absolute accuracy is dependent upon the exact optical wavelength. For the 6

specified wavelength, accuracy is ±3dB. See module specification sheet for range 7

over which accuracy requirement is met. 8

Tables 3.12 and 3.13 below illustrate the 16 bit signed twos complement format used for 9

temperature reporting. The most significant bit (D7) represents the sign, which is zero 10

for positive temperatures and one for negative temperatures. 11

Table 3.12: Bit weights (°C) for temperature reporting registers 12

Table 3.13: Digital temperature format 16

Most Significant Byte (byte 96) Least Significant Byte (byte 97)

D7 D6

D5 D4 D3 D2 D1 D0

D7 D6 D5 D4 D3 D2

D1 D0

SIGN 64 32 16 8 4 2 1 1/2 1/4 1/8 1/16 1/32 1/64 1/128 1/256

Temperature

BINARY HEXADECIMAL

DECIMAL FRACTION HIGH BYTE LOW BYTE HIGH BYTE LOW BYTE

+127.996 +127 255/256 01111111 11111111 7F FF

+125.000 +125 01111101 00000000 7D 00

+25.000 +25 00011001 00000000 19 00

+1.004 +1 1/256 00000001 00000001 01 01

+1.000 +1 00000001 00000000 01 00

+0.996 +255/256 00000000 11111111 00 FF

+0.004 +1/256 00000000 00000001 00 01

0.000 0 00000000 00000000 00 00

-0.004 -1/256 11111111 11111111 FF FF

-1.000 -1 11111111 00000000 FF 00

-25.000 -25 11100111 00000000 E7 00

-40.000 -40 11011000 00000000 D8 00

-127.996 -127 255/256 10000000 00000001 80 01

-128.000 -128 10000000 00000000 80 00

AN-2030: Digital Diagnostic Monitoring Interface for Optical Transceivers F i n i s a r

9/26/02 Revision D Page 19

External Calibration 1

Measurements are raw A/D values and must be converted to real units using calibration 2

constants stored in EEPROM locations 56 – 95 at 2 wire serial bus address A2h (see 3

Table 3.15). Calibration is valid over specified device operating temperature and 4

voltage. Alarm and warning threshold values should be interpreted in the same manner 5

as real time 16 bit data. 6

1) Internally measured transceiver temperature. Module temperature, T, is given by the 7

following equation: T(C) = T

slope

* T

(16 bit signed twos complement value) + T

offset

. 8

The result is in units of 1/256C, yielding a total range of –128C to +128C. See Table 9

3.15 for locations of T

SLOPE

and T

OFFSET

. Temperature measurement is valid from –10

40°C to +125°C with an accuracy of ± 3°C. The temperature sensor is located in the 11

center of the module and is typically 5 to 10 degrees hotter than the module case. See 12

Tables 3.12 and 3.13 above for examples of temperature format. 13

2) Internally measured transceiver supply voltage. Module internal supply voltage, V, is 14

given in microvolts by the following equation: V(µV) = V

SLOPE

* V

(16 bit unsigned 15

integer)

+ V

OFFSET

. The result is in units of 100µV, yielding a total range of 0 – 6.55V. 16

See Table 3.15 for locations of V

SLOPE

and V

OFFSET

. Accuracy is ±100mV. 17

3) Measured transmitter laser bias current. Module laser bias current, I, is given by the 18

following equation: I(µA) = I

SLOPE

* I

(16 bit unsigned integer) + I

OFFSET

. This result is 19

in units of 2 µA, yielding a total range of 0 to 131 mA. See Table 3.15 for locations of 20

SLOPE

and I

OFFSET

. Accuracy is ± 10%. Early versions of the digital diagnostic standard 21

(SFF-8472) used a scale factor of 1µA/AD Count for interpreting laser bias current 22

readings. SFF-8472 later changed the scale factor to the current value of 2µA/AD 23

Count. All Finisar modules using a scale factor of 2µA/AD Count have an ASCII “A” 24

written in byte 56 of the ‘vendor rev’ field (see table 3.1). Legacy Finisar modules using 25

a scale factor of 1µA/AD Count contain either zero or ASCII space (20h) or one of two 26

place holders: “X1—“, “1A—“, in location 56. 27

4) Measured coupled TX output power. Module transmitter coupled output power, 28

TX_PWR, is given in µW by the following equation: TX_PWR (µW) = TX_PWR

SLOPE

* 29

TX_PWR

(16 bit unsigned integer)

+ TX_PWR

OFFSET

. This result is in units of 0.1µW 30

yielding a total range of 0 – 6.5mW. See Table 3.15 for locations of TX_PWR

SLOPE

and 31

TX_PWR

OFFSET

. Data is factory calibrated to absolute units using the most 32

representative fiber output type. Accuracy is ±3dB. Data is not valid when the 33

transmitter is disabled. 34

AN-2030: Digital Diagnostic Monitoring Interface for Optical Transceivers F i n i s a r

9/26/02 Revision D Page 20

5) Measured received optical power. Received power, RX_PWR, is given in µW by 1

the following equation: 2

Rx_PWR (µW) = Rx_PWR(4) * Rx_PWR

(16 bit unsigned integer)

+ 3

Rx_PWR(3)*Rx_PWR

(16 bit unsigned integer)

+ Rx_PWR(2)*Rx_PWR

(16 bit 4

unsigned integer)

+ Rx_PWR(1) *Rx_PWR

(16 bit unsigned integer) + Rx_PWR(0) 5

The result is in units of 0.1µW yielding a total range of 0 – 6.5mW. See Table 3.15 for 6

locations of Rx_PWR(4-0). Absolute accuracy is dependent upon the exact optical 7

wavelength. For the specified wavelength, accuracy shall be better than ±3dB over 8

specified temperature and voltage. See module specification sheet for range over 9

which accuracy requirement is met. 10

Alarm and Warning Thresholds 12

Each A/D quantity has a corresponding high alarm, low alarm, high warning and low 13

warning threshold. These factory preset values allow the user to determine when a 14

particular value is outside of “normal” limits. These values vary with different 15

technologies and implementations. 16

Table 3.14: Alarm and Warning Thresholds (2-Wire Address A2h) 18

Address # Bytes Name Description

00-01 2 Temp High Alarm MSB at low address

02-03 2 Temp Low Alarm

MSB at low address

04-05 2 Temp High Warning

MSB at low address

06-07 2 Temp Low Warning

MSB at low address

08-09 2 Voltage High Alarm

MSB at low address

10-11 2 Voltage Low Alarm

MSB at low address

12-13 2 Voltage High Warning

MSB at low address

14-15 2 Voltage Low Warning

MSB at low address

16-17 2 Bias High Alarm

MSB at low address

18-19 2 Bias Low Alarm

MSB at low address

20-21 2 Bias High Warning

MSB at low address

22-23 2 Bias Low Warning

MSB at low address

24-25 2 TX Power High Alarm

MSB at low address

26-27 2 TX Power Low Alarm

MSB at low address

28-29 2 TX Power High Warning

MSB at low address

30-31 2 TX Power Low Warning

MSB at low address

32-33 2 RX Power High Alarm

MSB at low address

34-35 2 RX Power Low Alarm

MSB at low address

36-37 2 RX Power High Warning

MSB at low address

38-39 2 RX Power Low Warning

MSB at low address

40-55 16 Reserved Reserved for future monitored quantities

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Finisar AN-2030 User manual

Brand: Finisar

Model: AN-2030

Category: Network transceiver modules

Type: User manual

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Finisar AN-2030 User manual

Finisar AN-2030 User manual

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